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This article is a step-by-step guide to assembling and publishing a small, open-source Python package; topics covered include directory structure, basic unit tests, basic continuous integration setup, and publication to a repository.

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guide-to-publishing-packages

This article is a step-by-step guide to assembling and publishing a small, open-source Python package. While not all of the steps below will be appropriate or desirable for every package, each of these can contribute to the accessibility and maintainability of the package. Note that this material is meant to serve as a roadmap and overview; it is not a thorough review of all the nuances and trade-offs involved. You are encouraged to consult additional resources (links are included throughout the text) for other options and viewpoints on how to approach every portion of the process.

Table of Contents

Each section covers a task or category of tasks related to organizing and publishing a package and, where appropriate, provides templates and examples.

Note that depending on when you are reading this article, some of the steps, templates, and examples may be out of date.

Project Organization and Directory Tree Template

The directory structure below is one way in which a hypothetical project called published might be organized.

├─ .gitignore ............. File name patterns for Git to ignore 
├─ .travis.yml ............ Travis CI configuration
│
├─ LICENSE ................ License under which project is distributed
├─ README.rst ............. Project README
├─ setup.cfg .............. Configuration with parameters for setup
├─ setup.py ............... Package file
│
├─ published/
│  ├─ __init__.py ......... Namespace module
│  └─ published.py ........ Library module
│
└─ test/
   └─ test_published.py ... Unit tests

For the purposes of this article, it is assumed that the package contains just one source module (i.e., published/published.py). Therefore, it is sufficient to place it (along with its namespace module published/__init__.py) into its own directory. The sections below go into more detail about each of the files and their purpose.

Package File Organization

The setup.py package file specifies relevant metadata associated with your project, the locations of some important project files, and the dependencies that your project requires. An example of a possible setup.py file for the hypothetical package called published is presented below.

from setuptools import setup

with open("README.rst", "r") as fh:
    long_description = fh.read()

setup(
    name="published",
    version="0.1.0",
    packages=["published",],
    install_requires=[],
    license="MIT",
    url="https://pypi.org/project/published",
    author="python.supply",
    author_email="[email protected]",
    description="Example illustrating how an open-source library "+\
                "can be organized and published.",
    long_description=long_description,
    long_description_content_type="text/x-rst",
    test_suite="nose.collector",
    tests_require=["nose"],
)

Establishing and Checking Style Conventions

One easy way to add linting to your project is to create a default configuration file for Pylint.

python -m pip install pylint
pylint --generate-rcfile > .pylintrc

You can then check your project source files in the following way.

pylint published

In some cases, you may find it necessary to alter certain parameters in the configuration.

  • The variable-rgx, class-rgx, constant-rgx, and similar parameters can be used to specify an alternate standard for acceptable naming conventions. This can be reasonable to do in certain scenarios. For example, if you are implementing a specialized library that involves certain mathematical constructs, it may be more clear to your audience and in accordance with domain conventions to use single-letter variables such as x and y rather than longer identifiers that use snake case.
  • You might add rules that you want to ignore to the comma-separated list that follows the disable= parameter.

You may also want to direct Pylint to ignore a rule in a specific location within a source file. This can be done using a directive inside a comment. An example is presented below.

class published(): # pylint: disable=C0103,R0903
    def __init__(self):
        self.published = True

Defining Unit Tests and Measuring Test Coverage

There is an extensive supply of tools, packages, and conventions for defining unit tests, running unit tests, and measuring unit test coverage. In this article, the focus is on techniques that are suitable for small Python libraries and packages, so only two approaches are presented.

Using doctest

Unit tests for individual classes and methods can be included inside the docstrings that appear at the top of their bodies. The built-in doctest module can then be used to find and validate them. In the example below, the definition for the class published includes one such collection of tests in its docstring (i.e., a sequence of executed statements and the corresponding results, as might be observed when engaging a session via the interactive prompt).

class published(): # pylint: disable=C0103,R0903
    """
    A published package.

    >>> p = published()
    >>> p.is_published()
    True
    >>> p.published = False
    >>> p.is_published()
    Traceback (most recent call last):
      ...
    RuntimeError: package must be published
    """
    def __init__(self):
        """Build an instance."""
        self.published = True

    def is_published(self):
        """Check publication status."""
        if not self.published:
            raise RuntimeError("package must be published")

        return self.published

To check if the outputs in these sequences are accurate descriptions of what is actually returned by the Python interpreter when it runs each statement, simply add the following to your main module (e.g., inside published.py in this case):

if __name__ == "__main__":
    doctest.testmod()

It is then possible to run these tests as follows (the -v option ensures a report is displayed even if all tests succeed):

python published/published.py -v

Alternatively, you can allow nose to find and run doctests using appropriate parameters in a setup.cfg file. An example of a setup.cfg file that is sufficient for the examples above is presented below.

[nosetests]
exe=True
tests=published/published.py

Using unittest

If you would like to employ a more extensive test suite, you can create one using the built-in unittest library and put it in a location that the nose tool can locate automatically. Below is an example of the layout a test script test/test_published.py might have.

from unittest import TestCase
from published.published import published

class Test_published(TestCase):
    def test_is_published(self):
        p = published()
        self.assertTrue(p.is_published())

To ensure nose can find the test script, the setup.cfg configuration file should specify the directory that contains the test script.

[nosetests]
exe=True
with-doctest=1
tests=test/

Using both doctest and unittest with nose

It is possible to use nosetests to run all tests, including both doctest unit tests and any testing scripts. An example of a setup.cfg file that enables this is provided below.

[nosetests]
exe=True
with-doctest=1
tests=published/published.py, test/

Measuring coverage

To determine how much of your code is covered by unit tests every time you use nose, you can add a few optional lines to the setup.cfg file.

[nosetests]
exe=True
with-doctest=1
cover-package=published
cover-html=1
tests=published/published.py, test/

By assigning your package name to cover-package, you are indicating that coverage should be measured (typically using coverage). By assigning 1 to cover-html, you are indicating that human-readable HTML files should be generated that highlight what portions of the module files are not covered by any unit tests.

Continuous Integration and Coverage Reporting

You can connect your GitHub personal or organization account with Travis CI and Coveralls in order to automatically run tests and publish test coverage every time you or a contributor pushes to the package's GitHub repository or makes a pull request. Travis CI and Coveralls provide extensive documentation describing how you can link your GitHub account with their services; this article focuses is on what configuration files you need to add to your project.

A template for a simple .travis.yml Travis CI configuration file for the hypothetical package called published is provided below.

notifications:
  email:
    on_success: never
    on_failure: always
language: python
python:
  - "3.8"
cache: pip
install:
  - pip install pylint
  - pip install coveralls
  - pip install .
script:
  - pylint published
  - nosetests
after_success:
  - coveralls

The notifications section indicates that email notifications should only be sent if any step in the script section produces any result other than 0 (usually indicating success) to the standard output. The pylint and nosetests commands conform to this convention. The after_success section includes an entry that publishes the coverage results via Coveralls if there are no linting issues and no errors arise when the unit tests are executed.

README Organization and Format

An effective README document might cover some of the following topics:

  • the purpose of the package/libary;
  • a quick start guide showing how a first-time user can begin using the package/library;
  • how to run unit tests and measure test coverage;
  • how others can contribute;
  • the versioning standards or conventions being used.

Two popular formats for a README file that are supported by GitHub and PyPI are Markdown and reStructuredText. You can also learn more about how to structure a README file for PyPI.

Badges

You may want to add badges to your README that provide information about the status of your project (e.g., the host package repository and version number of the latest release, the last Travis CI build outcome, test coverage statistics, and so on). This requires determining the image URL for the badge you want to display (for example, the badge image URL for last Travis CI build status for the hypothetical package called published might be https://travis-ci.com/python-supply/published.svg) and then inserting that image into your README document using the appropriate syntax. For example, when using the reStructuredText format, the badge section of the README.rst file for the package published might look as follows if it uses substitution definitions for images in order to include badges for PyPI, Travis CI, and Coveralls.

|pypi| |travis| |coveralls|

.. |pypi| image:: https://badge.fury.io/py/published.svg
   :target: https://badge.fury.io/py/published

.. |travis| image:: https://travis-ci.com/python-supply/published.svg
   :target: https://travis-ci.com/python-supply/published

.. |coveralls| image:: https://coveralls.io/repos/github/python-supply/published/badge.svg
   :target: https://coveralls.io/github/python-supply/published

Versioning and Contributions

When deciding how to assign version numbers to different versions or releases of your package, there are advantages to adopting a published standard. An example of a popular standard is Semantic Versioning 2.0.0. One benefit of a standard is that it makes it easier for anyone working with your package to understand what the difference between two versions signifies (e.g., whether they can expect one version to be backwards compatible with another). Another benefit is that it reduces the burden on you as the author and maintainer, as you do not need to invest effort in documenting your own conventions and resolving any corner cases that might arise. Of course, this may come at some cost or additional effort if your goal is to adhere to the standard consistently.

You may also want to specify in the README document any expectations you have of contributors who may be interested in reporting issues or making improvements to your package. For example, you might direct potential contributors to report problems via GitHub Issues and to submit suggested fixes or enhancements via pull requests.

Publishing to PyPI

Once you are ready to publish your package, you may want to test one last time that the package file and other project files are organized appropriately by installing the package locally.

python -m pip install .

You can then generate the archive files for distribution.

python setup.py sdist bdist_wheel

These can then be contributed to PyPI after you have set up an account. When you run the command below for the first time, you will be asked for your PyPI credentials.

twine upload dist/*

You can then try installing your package from PyPI.

python -m pip install published

If you already installed a version locally, you may want to ensure you upgrade to the latest version using the --upgrade and --force-reinstall options.

python -m pip install --upgrade --force-reinstall published

Further Reading

This guide provides templates and examples that are just one path, involving a minimal number of steps, to organizing and publishing a small package. Not all of these steps may be appropriate for your particular package, and there are many variations and extensions of what is presented here. For a more detailed guide to packaging and publishing, you might want to refer to the Python Packaging User Guide and the Setuptools documentation. You may also want to explore alternatives that may exist for every step in this guide:

When evaluating alternatives, it is a good idea to check the level of activity in the community surrounding them, in addition to their suitability for your particular package. The long-term maintainability and compatibility of your package may be impacted if the tools and frameworks on which it relies are not well-supported or are phased out.

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This article is a step-by-step guide to assembling and publishing a small, open-source Python package; topics covered include directory structure, basic unit tests, basic continuous integration setup, and publication to a repository.

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